/*
  Copyright (c) 2007-2012 Red Hat, Inc. <http://www.redhat.com>
  This file is part of GlusterFS.

  This file is licensed to you under your choice of the GNU Lesser
  General Public License, version 3 or any later version (LGPLv3 or
  later), or the GNU General Public License, version 2 (GPLv2), in all
  cases as published by the Free Software Foundation.
*/

#ifndef _GLUSTERFS3_H
#define _GLUSTERFS3_H

#include <sys/uio.h>

#include "xdr-generic.h"
#include "glusterfs3-xdr.h"
#include "glusterfs4-xdr.h"
#include "iatt.h"
#include "protocol-common.h"
#include "upcall-utils.h"

#define xdr_decoded_remaining_addr(xdr)        ((&xdr)->x_private)
#define xdr_decoded_remaining_len(xdr)         ((&xdr)->x_handy)
#define xdr_encoded_length(xdr) (((size_t)(&xdr)->x_private) - ((size_t)(&xdr)->x_base))
#define xdr_decoded_length(xdr) (((size_t)(&xdr)->x_private) - ((size_t)(&xdr)->x_base))


#define GF_O_ACCMODE           003
#define GF_O_RDONLY             00
#define GF_O_WRONLY             01
#define GF_O_RDWR               02
#define GF_O_CREAT            0100
#define GF_O_EXCL             0200
#define GF_O_NOCTTY           0400
#define GF_O_TRUNC           01000
#define GF_O_APPEND          02000
#define GF_O_NONBLOCK        04000
#define GF_O_SYNC           010000
#define GF_O_ASYNC          020000

#define GF_O_DIRECT         040000
#define GF_O_DIRECTORY     0200000
#define GF_O_NOFOLLOW      0400000
#define GF_O_NOATIME      01000000
#define GF_O_CLOEXEC      02000000

#define GF_O_LARGEFILE     0100000

#define GF_O_FMODE_EXEC        040

#define XLATE_BIT(from, to, bit)    do {                \
                if (from & bit)                         \
                        to = to | GF_##bit;             \
        } while (0)

#define UNXLATE_BIT(from, to, bit)  do {                \
                if (from & GF_##bit)                    \
                        to = to | bit;                  \
        } while (0)

#define XLATE_ACCESSMODE(from, to) do {                 \
                switch (from & O_ACCMODE) {             \
                case O_RDONLY: to |= GF_O_RDONLY;       \
                        break;                          \
                case O_WRONLY: to |= GF_O_WRONLY;       \
                        break;                          \
                case O_RDWR: to |= GF_O_RDWR;           \
                        break;                          \
                }                                       \
        } while (0)

#define UNXLATE_ACCESSMODE(from, to) do {               \
                switch (from & GF_O_ACCMODE) {          \
                case GF_O_RDONLY: to |= O_RDONLY;       \
                        break;                          \
                case GF_O_WRONLY: to |= O_WRONLY;       \
                        break;                          \
                case GF_O_RDWR: to |= O_RDWR;           \
                        break;                          \
                }                                       \
        } while (0)

static inline uint32_t
gf_flags_from_flags (uint32_t flags)
{
        uint32_t gf_flags = 0;

        XLATE_ACCESSMODE (flags, gf_flags);

        XLATE_BIT (flags, gf_flags, O_CREAT);
        XLATE_BIT (flags, gf_flags, O_EXCL);
        XLATE_BIT (flags, gf_flags, O_NOCTTY);
        XLATE_BIT (flags, gf_flags, O_TRUNC);
        XLATE_BIT (flags, gf_flags, O_APPEND);
        XLATE_BIT (flags, gf_flags, O_NONBLOCK);
        XLATE_BIT (flags, gf_flags, O_SYNC);
        XLATE_BIT (flags, gf_flags, O_ASYNC);

        XLATE_BIT (flags, gf_flags, O_DIRECT);
        XLATE_BIT (flags, gf_flags, O_DIRECTORY);
        XLATE_BIT (flags, gf_flags, O_NOFOLLOW);
#ifdef O_NOATIME
        XLATE_BIT (flags, gf_flags, O_NOATIME);
#endif
#ifdef O_CLOEXEC
        XLATE_BIT (flags, gf_flags, O_CLOEXEC);
#endif
        XLATE_BIT (flags, gf_flags, O_LARGEFILE);
        XLATE_BIT (flags, gf_flags, O_FMODE_EXEC);

        return gf_flags;
}

static inline uint32_t
gf_flags_to_flags (uint32_t gf_flags)
{
        uint32_t flags = 0;

        UNXLATE_ACCESSMODE (gf_flags, flags);

        UNXLATE_BIT (gf_flags, flags, O_CREAT);
        UNXLATE_BIT (gf_flags, flags, O_EXCL);
        UNXLATE_BIT (gf_flags, flags, O_NOCTTY);
        UNXLATE_BIT (gf_flags, flags, O_TRUNC);
        UNXLATE_BIT (gf_flags, flags, O_APPEND);
        UNXLATE_BIT (gf_flags, flags, O_NONBLOCK);
        UNXLATE_BIT (gf_flags, flags, O_SYNC);
        UNXLATE_BIT (gf_flags, flags, O_ASYNC);

        UNXLATE_BIT (gf_flags, flags, O_DIRECT);
        UNXLATE_BIT (gf_flags, flags, O_DIRECTORY);
        UNXLATE_BIT (gf_flags, flags, O_NOFOLLOW);
#ifdef O_NOATIME
        UNXLATE_BIT (gf_flags, flags, O_NOATIME);
#endif
#ifdef O_CLOEXEC
        UNXLATE_BIT (gf_flags, flags, O_CLOEXEC);
#endif
        UNXLATE_BIT (gf_flags, flags, O_LARGEFILE);
        UNXLATE_BIT (gf_flags, flags, O_FMODE_EXEC);

        return flags;
}


static inline void
gf_statfs_to_statfs (struct gf_statfs *gf_stat, struct statvfs *stat)
{
        if (!stat || !gf_stat)
                return;

	stat->f_bsize   =  (gf_stat->bsize);
	stat->f_frsize  =  (gf_stat->frsize);
	stat->f_blocks  =  (gf_stat->blocks);
	stat->f_bfree   =  (gf_stat->bfree);
	stat->f_bavail  =  (gf_stat->bavail);
	stat->f_files   =  (gf_stat->files);
	stat->f_ffree   =  (gf_stat->ffree);
	stat->f_favail  =  (gf_stat->favail);
	stat->f_fsid    =  (gf_stat->fsid);
	stat->f_flag    =  (gf_stat->flag);
	stat->f_namemax =  (gf_stat->namemax);
}


static inline void
gf_statfs_from_statfs (struct gf_statfs *gf_stat, struct statvfs *stat)
{
        if (!stat || !gf_stat)
                return;

	gf_stat->bsize   = stat->f_bsize;
	gf_stat->frsize  = stat->f_frsize;
	gf_stat->blocks  = stat->f_blocks;
	gf_stat->bfree   = stat->f_bfree;
	gf_stat->bavail  = stat->f_bavail;
	gf_stat->files   = stat->f_files;
	gf_stat->ffree   = stat->f_ffree;
	gf_stat->favail  = stat->f_favail;
	gf_stat->fsid    = stat->f_fsid;
	gf_stat->flag    = stat->f_flag;
	gf_stat->namemax = stat->f_namemax;
}

static inline void
gf_proto_lease_to_lease (struct gf_proto_lease *gf_proto_lease, struct gf_lease *gf_lease)
{
        if (!gf_lease || !gf_proto_lease)
                return;

        gf_lease->cmd        = gf_proto_lease->cmd;
        gf_lease->lease_type = gf_proto_lease->lease_type;
        memcpy (gf_lease->lease_id, gf_proto_lease->lease_id, LEASE_ID_SIZE);
}

static inline void
gf_proto_lease_from_lease (struct gf_proto_lease *gf_proto_lease, struct gf_lease *gf_lease)
{
        if (!gf_lease || !gf_proto_lease)
                return;

        gf_proto_lease->cmd  = gf_lease->cmd;
        gf_proto_lease->lease_type = gf_lease->lease_type;
        memcpy (gf_proto_lease->lease_id, gf_lease->lease_id, LEASE_ID_SIZE);
}

static inline int
gf_proto_recall_lease_to_upcall (struct gfs3_recall_lease_req *recall_lease,
                                 struct gf_upcall *gf_up_data)
{
        struct gf_upcall_recall_lease *tmp = NULL;
        int    ret                         = 0;

        GF_VALIDATE_OR_GOTO(THIS->name, recall_lease, out);
        GF_VALIDATE_OR_GOTO(THIS->name, gf_up_data, out);

        tmp = (struct gf_upcall_recall_lease *)gf_up_data->data;
        tmp->lease_type = recall_lease->lease_type;
        memcpy (gf_up_data->gfid, recall_lease->gfid, 16);
        memcpy (tmp->tid, recall_lease->tid, 16);

        GF_PROTOCOL_DICT_UNSERIALIZE (THIS, tmp->dict,
                                      (recall_lease->xdata).xdata_val,
                                      (recall_lease->xdata).xdata_len, ret,
                                      errno, out);
out:
        return ret;

}

static inline int
gf_proto_recall_lease_from_upcall (xlator_t *this,
                                   struct gfs3_recall_lease_req *recall_lease,
                                   struct gf_upcall *gf_up_data)
{
        struct gf_upcall_recall_lease *tmp = NULL;
        int    ret                         = 0;

        GF_VALIDATE_OR_GOTO(this->name, recall_lease, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        tmp = (struct gf_upcall_recall_lease *)gf_up_data->data;
        recall_lease->lease_type = tmp->lease_type;
        memcpy (recall_lease->gfid, gf_up_data->gfid, 16);
        memcpy (recall_lease->tid, tmp->tid, 16);

        GF_PROTOCOL_DICT_SERIALIZE (this, tmp->dict,
                                    &(recall_lease->xdata).xdata_val,
                                    (recall_lease->xdata).xdata_len, ret, out);
out:
        return ret;

}

static inline void
gf_proto_flock_to_flock (struct gf_proto_flock *gf_proto_flock, struct gf_flock *gf_flock)
{
        if (!gf_flock || !gf_proto_flock)
                return;

	gf_flock->l_type     = gf_proto_flock->type;
	gf_flock->l_whence   = gf_proto_flock->whence;
	gf_flock->l_start    = gf_proto_flock->start;
	gf_flock->l_len      = gf_proto_flock->len;
	gf_flock->l_pid      = gf_proto_flock->pid;
        gf_flock->l_owner.len = gf_proto_flock->lk_owner.lk_owner_len;
        if (gf_flock->l_owner.len &&
            (gf_flock->l_owner.len < GF_MAX_LOCK_OWNER_LEN))
                memcpy (gf_flock->l_owner.data, gf_proto_flock->lk_owner.lk_owner_val,
                        gf_flock->l_owner.len);
}


static inline void
gf_proto_flock_from_flock (struct gf_proto_flock *gf_proto_flock, struct gf_flock *gf_flock)
{
        if (!gf_flock || !gf_proto_flock)
                return;

	gf_proto_flock->type     =  (gf_flock->l_type);
	gf_proto_flock->whence   =  (gf_flock->l_whence);
	gf_proto_flock->start    =  (gf_flock->l_start);
	gf_proto_flock->len      =  (gf_flock->l_len);
	gf_proto_flock->pid      =  (gf_flock->l_pid);
	gf_proto_flock->lk_owner.lk_owner_len =  gf_flock->l_owner.len;
        if (gf_flock->l_owner.len)
                gf_proto_flock->lk_owner.lk_owner_val = gf_flock->l_owner.data;
}

static inline void
gf_stat_to_iatt (struct gf_iatt *gf_stat, struct iatt *iatt)
{
        if (!iatt || !gf_stat)
                return;

        memcpy (iatt->ia_gfid, gf_stat->ia_gfid, 16);
	iatt->ia_ino = gf_stat->ia_ino ;
	iatt->ia_dev = gf_stat->ia_dev ;
	iatt->ia_type = ia_type_from_st_mode (gf_stat->mode) ;
	iatt->ia_prot = ia_prot_from_st_mode (gf_stat->mode) ;
	iatt->ia_nlink = gf_stat->ia_nlink ;
	iatt->ia_uid = gf_stat->ia_uid ;
	iatt->ia_gid = gf_stat->ia_gid ;
	iatt->ia_rdev = gf_stat->ia_rdev ;
	iatt->ia_size = gf_stat->ia_size ;
	iatt->ia_blksize = gf_stat->ia_blksize ;
	iatt->ia_blocks = gf_stat->ia_blocks ;
	iatt->ia_atime = gf_stat->ia_atime ;
	iatt->ia_atime_nsec = gf_stat->ia_atime_nsec ;
	iatt->ia_mtime = gf_stat->ia_mtime ;
	iatt->ia_mtime_nsec = gf_stat->ia_mtime_nsec ;
	iatt->ia_ctime = gf_stat->ia_ctime ;
	iatt->ia_ctime_nsec = gf_stat->ia_ctime_nsec ;
}

static inline void
gf_stat_from_iatt (struct gf_iatt *gf_stat, struct iatt *iatt)
{
        if (!iatt || !gf_stat)
                return;

        memcpy (gf_stat->ia_gfid, iatt->ia_gfid, 16);
	gf_stat->ia_ino = iatt->ia_ino ;
	gf_stat->ia_dev = iatt->ia_dev ;
	gf_stat->mode = st_mode_from_ia (iatt->ia_prot, iatt->ia_type);
	gf_stat->ia_nlink = iatt->ia_nlink ;
	gf_stat->ia_uid = iatt->ia_uid ;
	gf_stat->ia_gid = iatt->ia_gid ;
	gf_stat->ia_rdev = iatt->ia_rdev ;
	gf_stat->ia_size = iatt->ia_size ;
	gf_stat->ia_blksize = iatt->ia_blksize ;
	gf_stat->ia_blocks = iatt->ia_blocks ;
	gf_stat->ia_atime = iatt->ia_atime ;
	gf_stat->ia_atime_nsec = iatt->ia_atime_nsec ;
	gf_stat->ia_mtime = iatt->ia_mtime ;
	gf_stat->ia_mtime_nsec = iatt->ia_mtime_nsec ;
	gf_stat->ia_ctime = iatt->ia_ctime ;
	gf_stat->ia_ctime_nsec = iatt->ia_ctime_nsec ;
}

static inline int
gf_proto_cache_invalidation_from_upcall (xlator_t *this,
                                         gfs3_cbk_cache_invalidation_req *gf_c_req,
                                         struct gf_upcall *gf_up_data)
{
        struct gf_upcall_cache_invalidation *gf_c_data = NULL;
        int    is_cache_inval                          = 0;
        int    ret                                     = -1;

        GF_VALIDATE_OR_GOTO(this->name, gf_c_req, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        is_cache_inval = ((gf_up_data->event_type ==
                          GF_UPCALL_CACHE_INVALIDATION) ? 1 : 0);
        GF_VALIDATE_OR_GOTO(this->name, is_cache_inval, out);

        gf_c_data = (struct gf_upcall_cache_invalidation *)gf_up_data->data;
        GF_VALIDATE_OR_GOTO(this->name, gf_c_data, out);

        gf_c_req->gfid = uuid_utoa (gf_up_data->gfid);
        gf_c_req->event_type       = gf_up_data->event_type;
        gf_c_req->flags            = gf_c_data->flags;
        gf_c_req->expire_time_attr = gf_c_data->expire_time_attr;
        gf_stat_from_iatt (&gf_c_req->stat, &gf_c_data->stat);
        gf_stat_from_iatt (&gf_c_req->parent_stat, &gf_c_data->p_stat);
        gf_stat_from_iatt (&gf_c_req->oldparent_stat, &gf_c_data->oldp_stat);

        ret = 0;
        GF_PROTOCOL_DICT_SERIALIZE (this, gf_c_data->dict, &(gf_c_req->xdata).xdata_val,
                                    (gf_c_req->xdata).xdata_len, ret, out);
out:
        return ret;
}

static inline int
gf_proto_cache_invalidation_to_upcall (xlator_t *this,
                                       gfs3_cbk_cache_invalidation_req *gf_c_req,
                                       struct gf_upcall *gf_up_data)
{
        struct gf_upcall_cache_invalidation *gf_c_data = NULL;
        int    ret                                     = -1;

        GF_VALIDATE_OR_GOTO(this->name, gf_c_req, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        gf_c_data = (struct gf_upcall_cache_invalidation *)gf_up_data->data;
        GF_VALIDATE_OR_GOTO(this->name, gf_c_data, out);

        ret = gf_uuid_parse (gf_c_req->gfid, gf_up_data->gfid);
        if (ret) {
                gf_log (this->name, GF_LOG_WARNING, "gf_uuid_parse(%s) failed",
                        gf_c_req->gfid);
                gf_up_data->event_type = GF_UPCALL_EVENT_NULL;
                goto out;
        }

        gf_up_data->event_type      = gf_c_req->event_type;

        gf_c_data->flags            = gf_c_req->flags;
        gf_c_data->expire_time_attr = gf_c_req->expire_time_attr;
        gf_stat_to_iatt (&gf_c_req->stat, &gf_c_data->stat);
        gf_stat_to_iatt (&gf_c_req->parent_stat, &gf_c_data->p_stat);
        gf_stat_to_iatt (&gf_c_req->oldparent_stat, &gf_c_data->oldp_stat);

        ret = 0;
        GF_PROTOCOL_DICT_UNSERIALIZE (this, gf_c_data->dict,
                                      (gf_c_req->xdata).xdata_val,
                                      (gf_c_req->xdata).xdata_len, ret,
                                      ret, out);

        /* If no dict was sent, create an empty dict, so that each xlator
         * need not check if empty then create new dict. Will be unref'd by the
         * caller */
        if (!gf_c_data->dict)
                gf_c_data->dict = dict_new ();
  out:
        return ret;
}

static inline int
gf_proto_inodelk_contention_to_upcall (struct gfs4_inodelk_contention_req *lc,
                                       struct gf_upcall *gf_up_data)
{
        struct gf_upcall_inodelk_contention *tmp = NULL;
        xlator_t *this                           = NULL;
        int    ret                               = -1;
        int    op_errno                          = EINVAL;

        this = THIS;

        GF_VALIDATE_OR_GOTO(this->name, lc, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        tmp = (struct gf_upcall_inodelk_contention *)gf_up_data->data;

        gf_uuid_copy(gf_up_data->gfid, (unsigned char *)lc->gfid);

        gf_proto_flock_to_flock(&lc->flock, &tmp->flock);
        tmp->pid = lc->pid;
        tmp->domain = lc->domain;
        if ((tmp->domain != NULL) && (*tmp->domain == 0)) {
                tmp->domain = NULL;
        }

        GF_PROTOCOL_DICT_UNSERIALIZE (this, tmp->xdata, lc->xdata.xdata_val,
                                      lc->xdata.xdata_len, ret, op_errno, out);

        ret = 0;

out:
        if (ret < 0) {
                ret = -op_errno;
        }

        return ret;
}

static inline int
gf_proto_inodelk_contention_from_upcall (xlator_t *this,
                                         struct gfs4_inodelk_contention_req *lc,
                                         struct gf_upcall *gf_up_data)
{
        struct gf_upcall_inodelk_contention *tmp = NULL;
        int    ret                               = -1;
        int    op_errno                          = EINVAL;

        GF_VALIDATE_OR_GOTO(this->name, lc, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        tmp = (struct gf_upcall_inodelk_contention *)gf_up_data->data;

        gf_uuid_copy((unsigned char *)lc->gfid, gf_up_data->gfid);

        gf_proto_flock_from_flock(&lc->flock, &tmp->flock);
        lc->pid = tmp->pid;
        lc->domain = (char *)tmp->domain;
        if (lc->domain == NULL) {
                lc->domain = "";
        }

        GF_PROTOCOL_DICT_SERIALIZE (this, tmp->xdata, &lc->xdata.xdata_val,
                                    lc->xdata.xdata_len, op_errno, out);

        ret = 0;

out:
        if (ret < 0) {
                ret = -op_errno;
        }

        return ret;
}

static inline int
gf_proto_entrylk_contention_to_upcall (struct gfs4_entrylk_contention_req *lc,
                                       struct gf_upcall *gf_up_data)
{
        struct gf_upcall_entrylk_contention *tmp = NULL;
        xlator_t *this                           = NULL;
        int    ret                               = -1;
        int    op_errno                          = EINVAL;

        this = THIS;

        GF_VALIDATE_OR_GOTO(this->name, lc, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        tmp = (struct gf_upcall_entrylk_contention *)gf_up_data->data;

        gf_uuid_copy(gf_up_data->gfid, (unsigned char *)lc->gfid);

        tmp->type = lc->type;
        tmp->name = lc->name;
        if ((tmp->name != NULL) && (*tmp->name == 0)) {
                tmp->name = NULL;
        }
        tmp->pid = lc->pid;
        tmp->domain = lc->domain;
        if ((tmp->domain != NULL) && (*tmp->domain == 0)) {
                tmp->domain = NULL;
        }

        GF_PROTOCOL_DICT_UNSERIALIZE (this, tmp->xdata, lc->xdata.xdata_val,
                                      lc->xdata.xdata_len, ret, op_errno, out);

        ret = 0;

out:
        if (ret < 0) {
                ret = -op_errno;
        }

        return ret;
}

static inline int
gf_proto_entrylk_contention_from_upcall (xlator_t *this,
                                         struct gfs4_entrylk_contention_req *lc,
                                         struct gf_upcall *gf_up_data)
{
        struct gf_upcall_entrylk_contention *tmp = NULL;
        int    ret                               = -1;
        int    op_errno                          = EINVAL;

        GF_VALIDATE_OR_GOTO(this->name, lc, out);
        GF_VALIDATE_OR_GOTO(this->name, gf_up_data, out);

        tmp = (struct gf_upcall_entrylk_contention *)gf_up_data->data;

        gf_uuid_copy((unsigned char *)lc->gfid, gf_up_data->gfid);

        lc->type = tmp->type;
        lc->name = (char *)tmp->name;
        if (lc->name == NULL) {
                lc->name = "";
        }
        lc->pid = tmp->pid;
        lc->domain = (char *)tmp->domain;
        if (lc->domain == NULL) {
                lc->domain = "";
        }

        GF_PROTOCOL_DICT_SERIALIZE (this, tmp->xdata, &lc->xdata.xdata_val,
                                    lc->xdata.xdata_len, op_errno, out);

        ret = 0;

out:
        if (ret < 0) {
                ret = -op_errno;
        }

        return ret;
}

static inline void
gfx_stat_to_iattx (struct gfx_iattx *gf_stat, struct iatt *iatt)
{
        if (!iatt || !gf_stat)
                return;

        memcpy (iatt->ia_gfid, gf_stat->ia_gfid, 16);

        iatt->ia_flags = gf_stat->ia_flags;
	iatt->ia_ino = gf_stat->ia_ino ;
	iatt->ia_dev = gf_stat->ia_dev ;
	iatt->ia_rdev = gf_stat->ia_rdev ;
	iatt->ia_size = gf_stat->ia_size ;
	iatt->ia_nlink = gf_stat->ia_nlink ;
	iatt->ia_uid = gf_stat->ia_uid ;
	iatt->ia_gid = gf_stat->ia_gid ;
	iatt->ia_blksize = gf_stat->ia_blksize ;
	iatt->ia_blocks = gf_stat->ia_blocks ;
	iatt->ia_atime = gf_stat->ia_atime ;
	iatt->ia_atime_nsec = gf_stat->ia_atime_nsec ;
	iatt->ia_mtime = gf_stat->ia_mtime ;
	iatt->ia_mtime_nsec = gf_stat->ia_mtime_nsec ;
	iatt->ia_ctime = gf_stat->ia_ctime ;
	iatt->ia_ctime_nsec = gf_stat->ia_ctime_nsec ;
	iatt->ia_btime = gf_stat->ia_btime ;
	iatt->ia_btime_nsec = gf_stat->ia_btime_nsec ;
        iatt->ia_attributes = gf_stat->ia_attributes;
        iatt->ia_attributes_mask = gf_stat->ia_attributes_mask;

	iatt->ia_type = ia_type_from_st_mode (gf_stat->mode);
	iatt->ia_prot = ia_prot_from_st_mode (gf_stat->mode);
}


static inline void
gfx_stat_from_iattx (struct gfx_iattx *gf_stat, struct iatt *iatt)
{
        if (!iatt || !gf_stat)
                return;

        memcpy (gf_stat->ia_gfid, iatt->ia_gfid, 16);
	gf_stat->ia_ino = iatt->ia_ino ;
	gf_stat->ia_dev = iatt->ia_dev ;

	gf_stat->ia_nlink = iatt->ia_nlink ;
	gf_stat->ia_uid = iatt->ia_uid ;
	gf_stat->ia_gid = iatt->ia_gid ;
	gf_stat->ia_rdev = iatt->ia_rdev ;
	gf_stat->ia_size = iatt->ia_size ;
	gf_stat->ia_blksize = iatt->ia_blksize ;
	gf_stat->ia_blocks = iatt->ia_blocks ;
	gf_stat->ia_atime = iatt->ia_atime ;
	gf_stat->ia_atime_nsec = iatt->ia_atime_nsec ;
	gf_stat->ia_mtime = iatt->ia_mtime ;
	gf_stat->ia_mtime_nsec = iatt->ia_mtime_nsec ;
	gf_stat->ia_ctime = iatt->ia_ctime ;
	gf_stat->ia_ctime_nsec = iatt->ia_ctime_nsec ;

        gf_stat->ia_flags = iatt->ia_flags;
        gf_stat->ia_btime = iatt->ia_btime ;
	gf_stat->ia_btime_nsec = iatt->ia_btime_nsec ;
        gf_stat->ia_attributes = iatt->ia_attributes;
        gf_stat->ia_attributes_mask = iatt->ia_attributes_mask;

        gf_stat->mode   = st_mode_from_ia (iatt->ia_prot, iatt->ia_type);
}

/* dict_to_xdr () */
static inline int
dict_to_xdr (dict_t *this, gfx_dict *dict)
{
        int ret = -1;
        int i = 0;
        int index = 0;
        data_pair_t *dpair = NULL;
        gfx_dict_pair *xpair = NULL;
        ssize_t size = 0;

        /* This is a failure as we expect destination to be valid */
        if (!dict)
                goto out;

        /* This is OK as dictionary can be null, in which case, destination
           should also know that it is NULL. */
        if (!this) {
                /* encode special meaning data here,
                   while decoding, you know it is NULL dict */
                dict->count = -1;
                /* everything else is normal */
                dict->pairs.pairs_len = 0;
                ret = 0;
                goto out;
        }

        /* Do the whole operation in locked region */
        LOCK (&this->lock);

        dict->pairs.pairs_val = GF_CALLOC (1, (this->count *
                                               sizeof (gfx_dict_pair)),
                                           gf_common_mt_char);
        if (!dict->pairs.pairs_val)
                goto out;

        dpair = this->members_list;
        for (i = 0; i < this->count; i++) {
                xpair = &dict->pairs.pairs_val[index];

                xpair->key.key_val = dpair->key;
                xpair->key.key_len = strlen (dpair->key) + 1;
                xpair->value.type = dpair->value->data_type;
                switch (dpair->value->data_type) {
                        /* Add more type here */
                case GF_DATA_TYPE_INT:
                        index++;
                        xpair->value.gfx_value_u.value_int =
                                strtoll (dpair->value->data, NULL, 0);
                        break;
                case GF_DATA_TYPE_UINT:
                        index++;
                        xpair->value.gfx_value_u.value_uint =
                                strtoull (dpair->value->data, NULL, 0);
                        break;
                case GF_DATA_TYPE_DOUBLE:
                        index++;
                        xpair->value.gfx_value_u.value_dbl =
                                strtod (dpair->value->data, NULL);
                        break;
                case GF_DATA_TYPE_STR:
                        index++;
                        xpair->value.gfx_value_u.val_string.val_string_val = dpair->value->data;
                        xpair->value.gfx_value_u.val_string.val_string_len = dpair->value->len;
                        break;
                case GF_DATA_TYPE_IATT:
                        index++;
                        gfx_stat_from_iattx (&xpair->value.gfx_value_u.iatt,
                                             (struct iatt *)dpair->value->data);
                        break;
                case GF_DATA_TYPE_GFUUID:
                        index++;
                        memcpy (&xpair->value.gfx_value_u.uuid,
                                dpair->value->data, sizeof (uuid_t));
                        break;

                case GF_DATA_TYPE_PTR:
                        index++;
                        /* Ideally, each type of data stored in dictionary
                           should have type. A pointer type shouldn't be
                           sent on wire */

                        /* This is done for backward compatibility as dict is
                           heavily used for transporting data over wire.
                           Ideally, wherever there is an issue, fix and
			   move on */
                        xpair->value.gfx_value_u.other.other_val =
                                dpair->value->data;
                        xpair->value.gfx_value_u.other.other_len =
                                dpair->value->len;

                        /* Change this to INFO, after taking the above down */
                        gf_msg ("dict", GF_LOG_INFO, EINVAL,
                                LG_MSG_DICT_SERIAL_FAILED,
                                "key '%s' is would not be sent on wire in future",
                                dpair->key);
                        break;
                default:
                        /* Unknown type and ptr type is not sent on wire */
                        gf_msg ("dict", GF_LOG_WARNING, EINVAL, LG_MSG_DICT_SERIAL_FAILED,
                                "key '%s' is not sent on wire", dpair->key);
                        break;
                }
                dpair = dpair->next;
        }

        dict->pairs.pairs_len = index;
        dict->count = index;

        /* This is required mainly in the RPC layer to understand the
           boundary for proper payload. Hence only send the size of
           variable XDR size. ie, the formula should be:
           xdr_size = total size - (xdr_size + count + pairs.pairs_len))  */
        size = xdr_sizeof ((xdrproc_t) xdr_gfx_dict, dict);

        dict->xdr_size = (size > 12) ? (size - 12) : 0;

        ret = 0;
out:
        /* this can be null here, so unlock only if its not null */
        if (this)
                UNLOCK (&this->lock);

        return ret;
}

static inline int
xdr_to_dict (gfx_dict *dict, dict_t **to)
{
        int ret = -1;
        int index = 0;
        char *key = NULL;
        char *value = NULL;
        gfx_dict_pair *xpair = NULL;
        dict_t *this = NULL;
        unsigned char *uuid = NULL;
        struct iatt *iatt = NULL;

        if (!to || !dict)
                goto out;

        if (dict->count < 0) {
                /* indicates NULL dict was passed for encoding */
                ret = 0;
                goto out;
        }

        this = dict_new();
        if (!this)
                goto out;

        for (index = 0; index < dict->pairs.pairs_len; index++) {
                ret = -1;
                xpair = &dict->pairs.pairs_val[index];

                key = xpair->key.key_val;
                switch (xpair->value.type) {
                        /* Add more type here */
                case GF_DATA_TYPE_INT:
                        ret = dict_set_int64 (this, key,
                                    xpair->value.gfx_value_u.value_int);
                        break;
                case GF_DATA_TYPE_UINT:
                        ret = dict_set_uint64 (this, key,
                                    xpair->value.gfx_value_u.value_uint);
                        break;
                case GF_DATA_TYPE_DOUBLE:
                        ret = dict_set_double (this, key,
                                    xpair->value.gfx_value_u.value_dbl);
                        break;
                case GF_DATA_TYPE_STR:
                        value = GF_CALLOC (1, xpair->value.gfx_value_u.val_string.val_string_len + 1,
                                           gf_common_mt_char);
                        if (!value) {
                                errno = ENOMEM;
                                goto out;
                        }
                        memcpy (value, xpair->value.gfx_value_u.val_string.val_string_val,
                                xpair->value.gfx_value_u.val_string.val_string_len);
                        free (xpair->value.gfx_value_u.val_string.val_string_val);
                        ret = dict_set_dynstr (this, key, value);
                        break;
                case GF_DATA_TYPE_GFUUID:
                        uuid = GF_CALLOC (1, sizeof (uuid_t), gf_common_mt_uuid_t);
                        if (!uuid) {
                                errno = ENOMEM;
                                goto out;
                        }
                        memcpy (uuid, xpair->value.gfx_value_u.uuid, sizeof (uuid_t));
                        ret = dict_set_gfuuid (this, key, uuid, false);
                        break;
                case GF_DATA_TYPE_IATT:
                        iatt = GF_CALLOC (1, sizeof (struct iatt), gf_common_mt_char);
                        if (!iatt) {
                                errno = ENOMEM;
                                goto out;
                        }
                        gfx_stat_to_iattx (&xpair->value.gfx_value_u.iatt, iatt);
                        ret = dict_set_iatt (this, key, iatt, false);
                        break;
                case GF_DATA_TYPE_PTR:
                        value = GF_CALLOC (1, xpair->value.gfx_value_u.other.other_len + 1,
                                           gf_common_mt_char);
                        if (!value) {
                                errno = ENOMEM;
                                goto out;
                        }
                        memcpy (value, xpair->value.gfx_value_u.other.other_val,
                                xpair->value.gfx_value_u.other.other_len);
                        free (xpair->value.gfx_value_u.other.other_val);
                        ret = dict_set_dynptr (this, key, value,
                                               xpair->value.gfx_value_u.other.other_len);
                        break;
                default:
                        ret = 0;
                        /* Unknown type and ptr type is not sent on wire */
                        break;
                }
                if (ret) {
                        gf_msg_debug (THIS->name, ENOMEM,
                                      "failed to set the key (%s) into dict",
                                      key);
                }
                free (xpair->key.key_val);
        }

        free (dict->pairs.pairs_val);
        ret = 0;

        /* If everything is fine, assign the dictionary to target */
        *to = this;
        this = NULL;

out:
        if (this)
                dict_unref (this);

        return ret;
}

#endif /* !_GLUSTERFS3_H */
